wind

VTT solves erosion in wind turbine blades problem with the help of artificial intelligence

VTT’s antiAGE project found a functional solution to the problem of erosion of materials used in wind turbine blades due to the effect of weather conditions, a problem that applies to the whole wind energy sector.

The erosion of wind turbine blade material is a surprisingly costly problem, which no one had been able to solve before. In its antiAGE project, VTT modelled the material problem and set out to solve it virtually. This is the first time that AI was used for developing a material solution in this scale.

In principle, it is possible to find an unlimited number of different variations for the material used in wind turbine blades composed of the same material components but differing slightly from one another. Of all these alternatives, one would need to find the one that is best suited for this particular purpose and meets its operational requirements.

“The blade material erodes due to the effect of rain, hailstones and sand dust, which significantly reduces the service life of wind turbines” said Principal Scientist Anssi Laukkanen from VTT. “Accelerated replacement of turbines becomes expensive: up to 2–4 percent of the value of all wind-generated power is lost as a result of this problem. It is a question of a classic problem within this particular industry that costs billions of euros and brings additional costs to all wind energy. As wind turbine sizes increase and wind farms are placed out on the sea in increasingly demanding conditions, the significance of the problem becomes emphasised”.

Laukkanen added that human perceptive skills are insufficient to visualise all the dimensions related to the optimisation of material solutions. AI, on the other hand, is capable of unravelling very complicated cause-and-effect relationships, simulating solutions and going through an infinite number of alternatives to find the one that works best in relation to the requirements set.

In principle, using AI, it would be possible to find a tailored material solution optimised for a specific purpose for every component of any single product. However, manufacturing of such highly tailored materials would be difficult if traditional manufacturing techniques were used. 3D printing, or additive manufacturing, offers an opportunity to produce the desired material in any shape without unreasonable costs. When applied like this, 3D printing will do exactly what it is supposed to do.

The results of the antiAGE project exceeded expectations. Through a design process using virtual testing and machine learning, VTT was able to develop an optimised solution to a very difficult material problem in less than a year: a highly durable material that hardens when exposed to mechanical stress.

“When we published the news about our solution, wind turbine manufacturers became immediately interested in it. We are now negotiating details with commercial operators” Laukkanen said.

VTT is also applying for additional funding for the project, since there are plenty of targets for optimised material solutions in other sectors of industry as well. The more complex the product, the more expensive it is to develop materials suited for a specific purpose, and the more difficult it is in general to find material solutions that perform well. AI allows such problems to be addressed with efficiency.